Slide 1/29 Learning Objectives In this chapter you will learn about: Reasons for using binary instead of decimal numbers Basic arithmetic operations using binary numbers Addition (+) Subtraction (-) Multiplication (*) Division (/) 49 Slide 2/29 1
Binary over Decimal Information is handled in a computer by electronic/ electrical components Electronic components operate in binary mode (can only indicate two states on (1) or off (0) Binary number system has only two digits (0 and 1), and is suitable for expressing two possible states In binary system, computer circuits only have to handle two binary digits rather than ten decimal digits causing: Simpler internal circuit design Less expensive More reliable circuits Arithmetic rules/processes possible with binary numbers 49 Slide 3/29 s of a Few Devices that work in Binary Mode Binary State On (1) Off (0) Bulb Switch Circuit Pulse 50 Slide 4/29 2
Binary Arithmetic Binary arithmetic is simple to learn as binary number system has only two digits 0 and 1 Following slides show rules and example for the four basic arithmetic operations using binary numbers 50 Slide 5/29 Binary Addition Rule for binary addition is as follows: 0 + 0 = 0 0 + 1 = 1 1 + 0 = 1 1 + 1 = 0 plus a carry of 1 to next higher column 50 Slide 6/29 3
Binary Addition ( 1) Add binary numbers 10011 and 1001 in both decimal and binary form Binary Decimal carry 11 carry 1 10011 19 +1001 +9 11100 28 In this example, carry are generated for first and second columns 51 Slide 7/29 Binary Addition ( 2) Add binary numbers 100111 and 11011 in both decimal and binary form Binary Decimal carry 11111 carry 1 100111 39 +11011 +27 1000010 66 The addition of three 1s can be broken up into two steps. First, we add only two 1s giving 10 (1 + 1 = 10). The third 1 is now added to this result to obtain 11 (a 1 sum with a 1 carry). Hence, 1 + 1 + 1 = 1, plus a carry of 1 to next higher column. 51 Slide 8/29 4
Binary Subtraction Rule for binary subtraction is as follows: 0-0 = 0 0-1 = 1 with a borrow from the next column 1-0 = 1 1-1 = 0 51 Slide 9/29 Binary Subtraction () Subtract 01110 2 from 10101 2 12 0202 10101-01110 00111 Note: Go through explanation given in the book 52 Slide 10/29 5
Complement of a Number Number of digits in the number C = B n - 1 - N Complement of the number Base of the number The number 52 Slide 11/29 Complement of a Number ( 1) Find the complement of 37 10 Since the number has 2 digits and the value of base is 10, (Base) n -1 = 10 2-1 = 99 Now 99-37 = 62 Hence, complement of 37 10 = 62 10 53 Slide 12/29 6
Complement of a Number ( 2) Find the complement of 6 8 Since the number has 1 digit and the value of base is 8, (Base) n -1 = 8 1-1 = 7 10 = 7 8 Now 7 8-6 8 = 1 8 Hence, complement of 6 8 = 1 8 53 Slide 13/29 Complement of a Binary Number Complement of a binary number can be obtained by transforming all its 0 s to 1 s and all its 1 s to 0 s Complement of 1 0 1 1 0 1 0 is 0 1 0 0 1 0 1 Note: Verify by conventional complement 53 Slide 14/29 7
Complementary Method of Subtraction Involves following 3 steps: Step 1: Find the complement of the number you are subtracting (subtrahend) Step 2: Add this to the number from which you are taking away (minuend) Step 3: If there is a carry of 1, add it to obtain the result; if there is no carry, recomplement the sum and attach a negative sign Complementary subtraction is an additive approach of subtraction 53 Slide 15/29 Complementary Subtraction ( 1) : Subtract 56 10 from 92 10 using complementary method. Step 1: Complement of 56 10 = 10 2-1 - 56 = 99 56 = 43 10 Step 2: 92 + 43 (complement of 56) = 135 (note 1 as carry) Step 3: 35 + 1 (add 1 carry to sum) The result may be verified using the method of normal subtraction: 92-56 = 36 Result = 36 53 Slide 16/29 8
Complementary Subtraction ( 2) Subtract 35 10 from 18 10 using complementary method. Step 1: Complement of 35 10 = 10 2-1 - 35 = 99-35 = 64 10 Step 2: 18 + 64 (complement of 35) 82 Step 3: Since there is no carry, re-complement the sum and attach a negative sign to obtain the result. Result = -(99-82) = -17 The result may be verified using normal subtraction: 18-35 = -17 53 Slide 17/29 Binary Subtraction Using Complementary Method ( 1) Subtract 0111000 2 (56 10 ) from 1011100 2 (92 10 ) using complementary method. 1011100 +1000111 (complement of 0111000) 10100011 0100100 1 (add the carry of 1) Result = 0100100 2 = 36 10 53 Slide 18/29 9
Binary Subtraction Using Complementary Method ( 2) Subtract 100011 2 (35 10 ) from 010010 2 (18 10 ) using complementary method. 010010 +011100 (complement of 100011) 101110 Since there is no carry, we have to complement the sum and attach a negative sign to it. Hence, Result = -010001 2 (complement of 101110 2 ) = -17 10 54 Slide 19/29 Binary Multiplication Table for binary multiplication is as follows: 0 x 0 = 0 0 x 1 = 0 1 x 0 = 0 1 x 1 = 1 55 Slide 20/29 10
Binary Multiplication ( 1) Multiply the binary numbers 1010 and 1001 1010 Multiplicand x1001 Multiplier 1010 Partial Product 0000 Partial Product 0000 Partial Product 1010 Partial Product 1011010 Final Product (Continued on next slide) 55 Slide 21/29 Binary Multiplication ( 2) (Continued from previous slide..) Whenever a 0 appears in the multiplier, a separate partial product consisting of a string of zeros need not be generated (only a shift will do). Hence, 1010 x1001 1010 1010SS (S = left shift) 1011010 55 Slide 22/29 11
Binary Division Table for binary division is as follows: 0 0 = Divide by zero error 0 1 = 0 1 0 = Divide by zero error 1 1 = 1 As in the decimal number system (or in any other number system), division by zero is meaningless The computer deals with this problem by raising an error condition called Divide by zero error 57 Slide 23/29 Rules for Binary Division 1. Start from the left of the dividend 2. Perform a series of subtractions in which the divisor is subtracted from the dividend 3. If subtraction is possible, put a 1 in the quotient and subtract the divisor from the corresponding digits of dividend 4. If subtraction is not possible (divisor greater than remainder), record a 0 in the quotient 5. Bring down the next digit to add to the remainder digits. Proceed as before in a manner similar to long division 57 Slide 24/29 12
Binary Division ( 1) Divide 100001 2 by 110 2 0101 (Quotient) 110 100001 110 1000 110 100 110 1001 110 (Dividend) 1 Divisor greater than 100, so put 0 in quotient 2 Add digit from dividend to group used above 3 Subtraction possible, so put 1 in quotient 4 Remainder from subtraction plus digit from dividend 5 Divisor greater, so put 0 in quotient 6 Add digit from dividend to group 7 Subtraction possible, so put 1 in quotient 11 Remainder 57 Slide 25/29 Additive Method of Multiplication and Division Most computers use the additive method for performing multiplication and division operations because it simplifies the internal circuit design of computer systems 4 x 8 = 8 + 8 + 8 + 8 = 32 56 Slide 26/29 13
Rules for Additive Method of Division Subtract the divisor repeatedly from the dividend until the result of subtraction becomes less than or equal to zero If result of subtraction is zero, then: quotient = total number of times subtraction was performed remainder = 0 If result of subtraction is less than zero, then: quotient = total number of times subtraction was performed minus 1 remainder = result of the subtraction previous to the last subtraction 58 Slide 27/29 Additive Method of Division () Divide 33 10 by 6 10 using the method of addition : 33-6 = 27 27-6 = 21 21-6 = 15 15-6 = 9 9-6 = 3 3-6 = -3 Total subtractions = 6 Since the result of the last subtraction is less than zero, Quotient = 6-1 (ignore last subtraction) = 5 Remainder = 3 (result of previous subtraction) 58 Slide 28/29 14
Key Words/Phrases Additive method of division Additive method of multiplication Additive method of subtraction Binary addition Binary arithmetic Binary division Binary multiplication Binary subtraction Complement Complementary subtraction Computer arithmetic 58 Slide 29/29 15